A method for distributing fuel in a fuel system of a motor vehicle. The method may be applied in a fuel system having a first fuel tank, where fuel is confined at a first pressure, and a second fuel tank, where fuel is confined at a second pressure greater than the first pressure. The method comprises releasing fuel already resident in the second fuel tank to the first fuel tank, and admitting fuel to the first and second fuel tanks simultaneously.
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1. A method for distributing fuel in a fuel system of a motor vehicle, the fuel system having a first fuel tank, where fuel is confined at a first pressure, and a second fuel tank, where fuel is confined at a second pressure greater than the first pressure, the method comprising:
releasing fuel already resident in the second fuel tank to the first fuel tank; and
admitting fuel to the first and second fuel tanks simultaneously.
14. A method for refueling a fuel system of a motor vehicle, the fuel system having a plurality of fuel tanks, the method comprising:
selecting an unfull first fuel tank from among the plurality of fuel tanks;
during a first refueling mode of the fuel system, admitting fuel to the unfull first fuel tank only;
during a second refueling mode of the fuel system:
selecting from among the plurality of fuel tanks a second fuel tank having a greater pressure than the unfull first fuel tank;
releasing fuel already resident in the second fuel tank to the unfull first fuel tank; and
admitting fuel to the second and unfull first fuel tanks simultaneously.
20. A method for refueling a fuel system of a motor vehicle with compressed natural gas, the fuel system having a plurality of fuel tanks, the method comprising:
selecting an unfull first fuel tank from among the plurality of fuel tanks;
during a first refueling mode of the fuel system, opening a first control valve to admit compressed natural gas to the unfull first fuel tank only;
during a second refueling mode of the fuel system:
selecting from among the plurality of fuel tanks a second fuel tank having a pressure of compressed natural gas greater than that of the unfull first fuel tank;
opening the first control valve and a second control valve to release compressed natural gas already resident in the second fuel tank to the unfull first fuel tank; and
admitting fuel to the second and unfull first fuel tanks simultaneously.
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The present application relates to the field of fuel systems, and more particularly, to compressed-gas fuel systems for motor vehicles.
Compressed gasses such as hydrogen, methane, and natural gas (CNG) are suitable fuels for internal combustion engines. In some localities, gaseous fuels may be less expensive than gasoline or diesel fuel in terms of their cost per energy equivalent. Further, in contrast to liquid fuels, gaseous fuel may be more accurately controlled at or near stoichiometry during an engine start, as less excess fueling is used to achieve desired combustion performance. Moreover, some gaseous fuels may have higher octane ratings than liquid fuels.
A challenge for gaseous fuel systems in motor vehicles is the low and temperature-dependent volumetric energy density of compressed-gas fuels. One consequence is that the mechanical work needed to fill a compressed-gas fuel tank may be a significant fraction of the total internal energy stored in the fuel tank. Further, as the density of a gas at constant pressure decreases with increasing temperature, the very act of filling the fuel tank may, under some conditions, increase the temperature of the gas such that a fuel tank filled to a constant pressure contains less fuel mass than would be present if the fuel tank was filled to the same pressure at ambient temperature.
Various attempts to address these issues have appeared. For example, U.S. Patent Application Publication 2007/0000563 provides a system for increasing the overall efficiency of a high-pressure gas-fueled vehicle and refilling station infrastructure. In the disclosed system, the evolved heat from high-pressure refueling is absorbed by a melting/solidifying medium inside the fuel tank, and may be dispersed via an external radiator. In this manner, a denser charge of fuel may be admitted to the fuel tank.
However, the approach cited above requires extensive hardware and special materials dedicated exclusively to temperature management. The inventors herein have recognized this limitation and have provided a more elegant approach that may be implemented in a motor-vehicle fuel system having multiple compressed-gas fuel tanks. Further, the system may be integrated with a method for minimizing the mechanical work needed to refill a fuel system having multiple fuel tanks.
Therefore, in one embodiment, a method for distributing fuel in a fuel system of a motor vehicle is provided. The method may be applied in a fuel system having a first fuel tank, where fuel is confined at a first pressure, and a second fuel tank, where fuel is confined at a second pressure greater than the first pressure. The method comprises releasing fuel already resident in the second fuel tank to the first fuel tank, and admitting fuel to the first and second fuel tanks simultaneously. Other embodiments provide other, more particular methods for distributing fuel in a fuel system of a motor vehicle. In this manner, a more simply configured fuel system may be operated to accommodate a denser charge of fuel than might otherwise be possible.
It will be understood that the summary above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description, which follows. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined by the claims that follow the detailed description. Further, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.
The subject matter of the present disclosure is now described by way of example and with reference to certain illustrated embodiments. Components that may be substantially the same in two or more embodiments are identified coordinately and are described with minimal repetition. It will be noted, however, that components identified coordinately in different embodiments of the present disclosure may be at least partly different. It will be further noted that the drawings included in this disclosure are schematic. Views of the illustrated embodiments are generally not drawn to scale; aspect ratios, feature size, and numbers of features may be purposely distorted to make selected features or relationships easier to see.
Industry standards may establish the type of fixture or fitting (viz., the configuration, dimensions, and/or materials thereof) through which one or more fuels may be supplied to fuel system 10 via fuel port 12. Industry standards may further establish an acceptable range of pressures at which one or more fuels are supplied to the fuel system. For example, hydrogen may be supplied at a pressure of approximately 5000 p.s.i., or CNG may be supplied at a pressure of approximately 3600 p.s.i. It will be understood that the supply pressures indicated herein are examples only, as other suitable pressures and pressure ranges are contemplated as well.
Continuing in
Fuel system 10 further includes fuel tanks 20A, 20B, 20C, and 20D, configured to store pressurized, gaseous fuel. Fluidically coupled to each of the fuel tanks is a temperature sensor and a pressure sensor. Accordingly, temperature sensor 22A and pressure sensor 24A are fluidically coupled to fuel tank 20A, temperature sensor 22B and pressure sensor 24B are fluidically coupled to fuel tank 20B, etc. Each temperature sensor is responsive to the temperature of the gas inside the fuel tank to which it is coupled, and each pressure sensor is responsive to the pressure of a gas inside the fuel tank to which it is coupled—either a relative pressure measured with respect to atmosphere, or an absolute pressure measured with respect to vacuum. In the embodiment illustrated in
During refueling, each fuel tank in fuel system 10 may be charged via a normally closed control valve fluidically coupled to fuel line 18. During operation of the motor vehicle, each fuel tank may be discharged to the fuel line through the same control valve. Accordingly, control valve 28A is fluidically coupled to fuel tank 20A, control valve 28B is fluidically coupled to fuel tank 20B, etc. Further, control valves 28A-D may be operatively coupled to electronic control system 26 such that each of the control valves may be opened, closed, and/or adjusted in response to a signal from the electronic control system via appropriate valve actuators (not shown in the drawings).
From fuel line 18, fuel flows through filter 30 to pressure regulator 32. The pressure regulator is configured to maintain a substantially constant pressure of fuel in fuel rail 34, via which fuel is supplied to fuel injectors 36 of an engine. The filter is configured to protect the pressure regulator and fuel injectors from damage due to particulate solids entrained in the gas stream.
The embodiment illustrated in
Other embodiments fully consistent with the present disclosure may include more or fewer fuel tanks, more or fewer pressure sensors, an/or more or fewer temperature sensors. In one embodiment, for example, a single pressure sensor may be fluidically coupled to the fuel line, and the temperature sensor may be an ambient temperature sensor. In this embodiment, the electronic control system may be configured to estimate the temperature of the fuel in each of the fuel tanks based on the ambient temperature and on the history of fuel-line pressure variations and valve openings/closures recorded in the electronic control system as a function of time.
The embodiments described above provide various advantages over existing motor-vehicle fuel systems in which a check valve is integrated in each of the control valves fluidically coupled to the fuel tanks. There, the integrated check valve may be coupled to both ends of the control valve and oriented to allow a fuel tank to fill whenever the pressure in the fuel line is greater than the pressure of the fuel tank. Fuel-tank assemblies including an integrated check valve and control valve are commercially available. One such fuel-tank assembly 20′ is shown by example in
Nevertheless, it may be desirable—e.g., to reduce manufacturing cost—to use one or more commercially available fuel system assemblies to enact the various fuel-distribution approaches disclosed herein. For example, it may be desirable to use fuel tank assembly 20′ in place of one or more of the fuel tanks in fuel system 10. If used in place of fuel tank 20A in fuel system 10, for instance, fuel tank assembly 20′ could be discharged when control valves 28A and 58 are both open, and charged when control valve 28A is open, but control valve 58 is closed. Likewise, if used in place of fuel tank 20A in fuel system 48, fuel tank assembly 20′ could be discharged when control valves 28A and 58 are both open, and charged whenever the pressure in fuel supply line 50 is greater than the pressure in fuel tank 60.
In still other another embodiments, control valves 28A-D in fuel system 10 may be normally open control valves. This variation will allow the fuel system to charge passively and discharge actively, substantially as described for fuel system 48.
The configurations illustrated above enable various methods for distributing fuel in a fuel system of a motor vehicle. Accordingly, some such methods are now described, by way of example, with continued reference to above configurations. It will be understood, however, that these methods, and others fully within the scope of the present disclosure, may be enabled via other configurations as well.
Method 62 and subsequent methods include various computation, comparison, and decision-making actions, which may be enacted via an electronic control system (e.g., electronic control system 26) of the fuel system or of a motor vehicle in which the fuel system is installed. The methods further include various measuring and/or sensing actions that may be enacted via one or more sensors disposed in the fuel system (pressure sensors, temperature sensors, breech sensors, etc.)—operatively coupled to the electronic control system, as described in the example configurations hereinabove. The methods further include various valve-actuating events, which the electronic control system may enact in response to the various decision-making actions.
Method 62 may be entered upon when the fuel system is releasing fuel from one or more fuel tanks via one or more control valves (control valve 28A, for example) open to fuel line 18. The method begins at 64, where Pline, the pressure of fuel in fuel line 18, is compared to a set-point pressure Preg of pressure regulator 32. In embodiments where a pressure sensor is coupled directly to the fuel line, the electronic control system may determine Pline directly. In other configurations, the electronic control system may determine or estimate Pline indirectly. In one embodiment, Pline may be calculated based on the output of a pressure sensor of a fuel tank that is open to the fuel line (one pressure sensors 24A-D, for example), and further based on a known flow rate through fuel injectors 36.
If it is determined that Pline is significantly greater than Preg, then method 62 returns to 64, where fuel continues to be released from the one or more fuel tanks currently open to the fuel line 18, and where the pressures are compared again. However, if it is determined that Pline is not significantly greater than Preg, then method 62 advances to 66.
At 66, all currently open control valves are closed, thereby preventing subsequent inflow of fuel to a depleted fuel tank when a fuller fuel tank opens to fuel line 18. Then, at 68, the electronic control system interrogates the fuel pressures of each fuel tank in the fuel system, attempting to identify a fuel tank having the lowest fuel pressure Ptank that is greater than the set-point pressure Preg. In fuel systems comprising a pressure sensor for each fuel tank, the fuel pressures may be interrogated simply by reading the response of each of the sensors. However, in embodiments where multiple fuel tanks share a common pressure sensor coupled to the fuel line or fuel-delivery line (viz., the high-pressure side of regulator 32), step 68 may comprise momentarily opening the control valves to each fuel tank in sequence to enable the common pressure sensor to sense the pressure in each fuel tank one at a time.
At 70, it is determined whether a fuel tank having a pressure greater than or equal to the set-point pressure can be found (i.e., identified) in the fuel system. If such a fuel tank is found, then at 72, the control valve linking the found fuel tank to the fuel line is open, allowing the fuel line to be sourced via the found fuel tank. In this manner, fuel is delivered from each fuel tank to a fueled component of the motor vehicle only after all other fuel tanks filled to a lesser pressure are depleted. Method 62 then returns to 64. However, if it is determined at 70 that no fuel tank can be found having Ptank>Preg, then at 74, the electronic control system registers and indicates a vacant condition of the fuel system.
The present disclosure contemplates other fuel-system discharging methods as well. For example, in fuel-system configurations as shown in
Method 76 begins at 78, where the electronic control system determines which of at least two possible refueling modes is selected: an ECONOMY mode or a EXTENDED-FILL mode. A motor-vehicle operator or filling-station attendant may select the refueling mode in any suitable manner. Accordingly, the fuel system may be configured to communicate the selected refueling mode to the electronic control system. The refueling mode may be communicated, for example, via a fuel door key position or other mechanical switch. A precondition for both refueling modes is that the fuel tanks of the fuel system were not all discharged simultaneously prior to the execution of method 76, so that at least one fuel tank in the fuel system will be filled to a greater pressure than at least one other fuel tank. This precondition may be satisfied by any method that discharges the fuel tanks sequentially, such as method 62, for example.
In ECONOMY mode, the fuel tanks are filled so as to minimize the mechanical work needed to admit a given mass of fuel into the fuel system. This is accomplished by refilling the fuel tanks without first equalizing the pressures of the fuel tanks. In EXTENDED-FILL mode, the fuel tanks are filled so as to maximize the total mass of fuel that may be added to the one or more unfull fuel tanks of the fuel system. This may be accomplished by precooling two or more fuel tanks by allowing gas from a fuller fuel tank to expand into at least one emptier fuel tank. After the expansion stage, fuel is supplied to the two or more precooled fuel tanks simultaneously. Delivering a given mass of fuel to the two or more fuel tanks after the expansion stage requires more mechanical work and releases more heat than delivering the same mass of fuel in ECONOMY mode. After the fuel is delivered, however, the final temperature of the fuel delivered to the two or more fuel tanks will be lower than in ECONOMY mode because the temperature of the two or more fuel tanks immediately after the expansion stage may be quite low. Therefore, a greater mass of fuel may be accommodated when the fuel system is filled in EXTENDED-FILL mode rather than ECONOMY mode.
Continuing in
Other fuel-system configurations, such as the one shown in
Method 82 begins at 84, where the control valve coupled to the lowest-pressure fuel tank is opened. The method then advances to 86, where one or more fuel tanks are identified whose pressures are less than or equal to the pressure of the fuel tank being filled. Control valves coupled to any such fuel tanks are then opened. The method then advances to 88, where it is determined whether to stop the refueling. The determination at 88 may be made automatically, based on whether the refill is complete (e.g., all control valves are open, and the pressure in the fuel line is approaching the supply pressure) or in response to a termination instruction from the motor-vehicle operator or filling station attendant. If it is determined not to stop the refueling, then the method returns to 86. Otherwise, the method advances to 90, where the control valves coupled to all fuel tanks in the fuel system are closed. Method 82 then returns.
Returning now to
If a suitable TANK1 is found, then method 76 advances to 98, where the electronic control system interrogates the fuel pressures of each fuel tank in the fuel system, attempting to identify a fuel tank of greater pressure than TANK1. At 100, it is determined whether such a fuel tank can be found in the fuel system. If no such fuel tank can be found, then the expansion stage referred to above may not be possible, and the method advances to 80, as in ECONOMY MODE. However, if it is determined that one or more fuel tanks having higher pressure than TANK1 are available, then the electronic control system selects TANK2 from among them. At 102, the control valve linking TANK2 to fuel line 18 is opened. Accordingly, TANK2 is selected from among the plurality of fuel tanks in the fuel system based on a fuel pressure of each fuel tank.
In other embodiments, TANK2 may be selected based on a fuel temperature instead of or in addition to the fuel pressure of each fuel tank in the fuel system. In particular, TANK2 may be chosen so that releasing fuel already resident in TANK2 into TANK1 provides a cooler temperature in TANK1 than releasing fuel already resident in any other fuel tank into TANK1. In still other embodiments, the determination of which fuel tank to select may be based on calculations or numerical simulations enacted in the electronic control system based on theoretical enthalpies for adiabatic expansion and/or adiabatic compression of the fuel.
Continuing in
In other embodiments fully consistent with this disclosure, TANK2 may be one of a plurality of fuel tanks from which fuel already resident in the fuel system is released to TANK1 prior to admitting the fuel to TANK1 and TANK2 simultaneously. Further, TANK1 may be one of a plurality of fuel tanks into which fuel already resident in the fuel system is released from the TANK2 prior to admitting the fuel to TANK1 and TANK2 simultaneously. Further still, the particular groups of tanks chosen in these cases may be based on which would ultimately enable the greatest mass of fuel to be accommodated in the fuel system during a subsequent or contemporaneous refill. This, in turn, may be based on the current fill state of each fuel tank and the predicted level of cooling for each fuel tank during an adiabatic expansion in several possible scenarios. Accordingly, electronic control system 26 may be configured to estimate the mass of fuel that could be accommodated under numerous possible equilibration/refilling scenarios, based on these considerations, and then select the scenario that accommodates the maximum total mass of fuel.
Continuing in
It will be further understood that the example control and estimation routines disclosed herein may be used with various system configurations. These routines may represent one or more different processing strategies such as event-driven, interrupt-driven, multi-tasking, multi-threading, and the like. As such, the disclosed process steps (operations, functions, and/or acts) may represent code to be programmed into computer readable storage medium in an electronic control system. It will be understood that some of the process steps described and/or illustrated herein may in some embodiments be omitted without departing from the scope of this disclosure. Likewise, the indicated sequence of the process steps may not always be required to achieve the intended results, but is provided for ease of illustration and description. One or more of the illustrated actions, functions, or operations may be performed repeatedly, depending on the particular strategy being used.
Finally, it will be understood that the articles, systems and methods described herein are exemplary in nature, and that these specific embodiments or examples are not to be considered in a limiting sense, because numerous variations are contemplated. Accordingly, the present disclosure includes all novel and non-obvious combinations and sub-combinations of the various systems and methods disclosed herein, as well as any and all equivalents thereof.
Pursifull, Ross Dykstra, Ulrey, Joseph Norman
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